Building Krylov complexity from circuit complexity
ORAL
Abstract
Krylov complexity has emerged as a new probe of operator growth in a wide range of non-
equilibrium quantum dynamics. However, a fundamental issue remains in such studies: the definition
of the distance between basis states in Krylov space is ambiguous. Here, we show that Krylov
complexity can be rigorously established from circuit complexity when dynamical symmetries exist.
Whereas circuit complexity characterizes the geodesic distance in a multi-dimensional operator
space, Krylov complexity measures the height of the final operator in a particular direction. The
geometric representation of circuit complexity thus unambiguously designates the distance between
basis states in Krylov space. This geometric approach also applies to time-dependent Liouvillian
superoperators, where a single Krylov complexity is no longer sufficient. Multiple Krylov complexity
may be exploited jointly to fully describe operator dynamics.
equilibrium quantum dynamics. However, a fundamental issue remains in such studies: the definition
of the distance between basis states in Krylov space is ambiguous. Here, we show that Krylov
complexity can be rigorously established from circuit complexity when dynamical symmetries exist.
Whereas circuit complexity characterizes the geodesic distance in a multi-dimensional operator
space, Krylov complexity measures the height of the final operator in a particular direction. The
geometric representation of circuit complexity thus unambiguously designates the distance between
basis states in Krylov space. This geometric approach also applies to time-dependent Liouvillian
superoperators, where a single Krylov complexity is no longer sufficient. Multiple Krylov complexity
may be exploited jointly to fully describe operator dynamics.
–
Presenters
-
Ren Zhang
Xi'an Jiaotong Univ
Authors
-
Ren Zhang
Xi'an Jiaotong Univ
-
Chenwei Lv
Purdue University
-
Qi Zhou
Purdue University